A Four-Base Paired Genetic Helix with Expanded Size Liu, Haibo; Gao, Jianmin; Lynch, Stephen R. ...
Science (American Association for the Advancement of Science),
10/2003, Letnik:
302, Številka:
5646
Journal Article
Recenzirano
We describe a new molecular class of genetic-pairing system that has a native DNA backbone but has all four base pairs replaced by new, larger pairs. The base pairs include size-expanded analogs of ...thymine and of adenine, both extended by the width of a benzene ring (2.4 Å). The expanded-diameter double helices are more thermodynamically stable than the Watson-Crick helix, likely because of enhanced base stacking. Structural data confirm a right-handed, double-stranded, and base-paired helical form. Because of the larger base size, all the pairs of this helical system are fluorescent, which suggests practical applications in detection of natural DNA and RNA. Our findings establish that there is no apparent structural or thermodynamic prohibition against genetic systems having sizes different from the natural one.
Recent studies have identified amino acid side chains forming several hydrogen bonds in the DNA minor groove as potentially important in polymerase replication of DNA. Few studies have probed these ...interactions on the DNA itself. Using non-hydrogen-bonding nucleoside isosteres, we have now studied effects in both primer and template strands with several polymerases to investigate the general importance of these interactions. All six polymerases show differences in the H-bonding effects in the minor groove. Two broad classes of activity are seen, with a first group of DNA polymerases (KF(-), Taq, and HIV-RT) that efficiently extends nonpolar base pairs containing nucleoside Q (9-methyl-1H-imidazo4,5-bpyridine) but not the analogue Z (4-methylbenzimidazole), implicating a specific minor groove interaction at the first extension site. A second group of polymerases (Pol alpha, Pol beta, and T7(-)) fails to extend all non-H-bonding base pairs, indicating that these enzymes may need minor groove hydrogen bonds at both minor groove sites or that they are especially sensitive to noncanonical DNA structure or stability. All DNA polymerases examined use energetically important minor groove interactions to probe newly synthesized base pairs before extending them. The positions of these interactions vary among the enzymes, and only a subset of the interactions identified structurally appears to be functionally important. In addition, polymerases appear to be differently sensitive to small changes in base pair geometry.
Recent studies have established the utility of oligonucleotide ligation methods in the detection of DNAs and RNAs in solution and in cellular imaging. Notably, the ligated full-length oligonucleotide ...products commonly bind to the target nucleic acid much more tightly than do the two starting half-probes, which effectively limits the resulting signals to one per target. Here, we report on a molecular strategy for destabilizing ligated products in template-promoted self-ligation reactions, thus yielding multiple signals per target. A new universal linker design is described in which a dabsyl leaving group is placed on a short alkane tether. This allows the placement of an electrophile at the end of any DNA sequence, in contrast to earlier ligation strategies, and it also speeds reaction rates by a factor of 4-5. This new class of molecular linker/activator yields as much as 92-fold amplification of signals in DNA and RNA detection, and proceeds without enzymes, added reagents, or thermal cycling. The linker is shown to destabilize the ligation product without destabilizing the transition state for ligation. This lowers product inhibition, and the target DNA or RNA thus becomes a catalyst for isothermally generating multiple signals for its detection. This enhanced signal generation is demonstrated in solution experiments and in solid supported assays.
The use of a simple fluorescent nucleoside analogue in detection of point mutations by hybridization in solution is described. Pyrene is placed at 3′ and 5′ ends of a pair of oligodeoxynucleotide ...probes via a phosphoramidite derivative of deoxyribose with this fluorophore attached at the 1′ position, replacing a DNA base. Adjacent binding of dual probes containing this fluorophore to a complementary target sequence results in a pronounced spectral change from blue pyrene monomer emission (λmax = 381 398 nm) to green-white excimer emission (λmax = 490 nm). Optimization of the relative binding positions of the two probes shows that the greatest spectral change occurs when they bind with partial end overlap. In optimum orientation, the monomer emission band for the probes decreases intensity by as much as a factor of seven and the excimer band increases up to 40-fold on binding a complementary target. Application to the detection of a single-base point mutation in solution is described.
We describe the properties of stable DNA-like self-assembled helices composed entirely of base pairs involving two new size-expanded pyrimidines. We term this new helix geometry "yDNA" (an ...abbreviation of "wide DNA"). The new pyrimidine analogues, yT and yC, are increased in size by benzo-homologation and have a geometry that is distinct from previous size-expanded pyrimidines. The yT and yC deoxyribosides were incorporated into oligodeoxynucleotides designed to form four pairs: yT-A, A-yT, yC-G, and G-yC. Helices were characterized by thermal denaturation, mixing data, and circular dichroism spectra. Results showed that highly stable double-stranded helices were formed in several sequence contexts. The data further showed that yT and yC could be segregated onto one strand and used to bind to natural strands of DNA with high sequence selectivity. The combination of yC, yT, G, and A make up a new selective, self-assembling four-base genetic pairing system that functions in many respects like natural DNA, but which is structurally distinct. The results establish that multiple variants of size-expanded DNA-like helices are feasible and suggest the possibility of a future eight-base genetic system based on the yDNA geometry. Finally, the high binding selectivity, affinity, and fluorescence of yDNA strands may yield useful applications in detection of nucleic acid sequences.
We describe the design, preparation, and properties of two key building blocks of a size-expanded genetic system. Nucleoside analogues of the natural nucleosides dA and dT are reported in which the ...fusion of a benzo ring increases their size by ca. 2.4 A. The expanded dA analogue (dxA), having a tricyclic base, was first reported by Leonard nearly three decades ago. We describe a shortened and more efficient approach to this compound. The expanded dT analogue (dxT), a methylquinazolinedione C-glycoside, was previously unknown; we describe its preparation in eight steps from 5-methylanthranilic acid. The key glycoside bond formation employed Pd-mediated coupling of an aryl iodide precursor with a dihydrofuran derivative of deoxyribose. Both nucleosides are shown to be efficient fluorophores, emitting light in the blue-violet range. The base-protected phosphoramidite derivatives were prepared, and short oligonucleotides containing them were characterized. The two size-expanded nucleosides are key components of a new four-base genetic system designed to form helical paired structures having a diameter greater than that of natural DNA. Elements of the design of this expanded genetic molecule, termed xDNA, are discussed, including the possibility of up to eight base pairs of information storage capability.
We describe physicochemical properties in DNA of altered-size nucleobases that retain Watson-Crick analogous hydrogen-bonding ability. Size-expanded analogues of adenine and thymine (xA and xT, ...respectively, which are expanded by benzo-fusion) were incorporated into natural DNA oligonucleotides, and their effects on helix stability were measured. Base stacking studies revealed that the two stretched analogues stack much more strongly than do their naturally sized counterparts. In contrast to this, pairing studies showed that single substitutions of the new bases are destabilizing to the natural helix as compared to A or T in standard A-T pairs in the same context, unless multiple adjacent substitutions are used. Interestingly, the size-expanded bases displayed selective recognition of the hydrogen-bonding complementary partners, suggesting that Watson-Crick analogous pairs were still formed despite local backbone strain. In an attempt to compensate for the added size of the expanded adenine, we tested a formamide deoxynucleoside, which Leonard proposed as a shortened thymine analogue (F(o)). Data showed, however, that this compound adopts a conformation unfavorable for pairing. On the basis of the combined thermodynamic data, we estimate the energetic cost of the 2.4 A stretching of an isolated base pair in DNA at ca. +1 to 2 kcal/mol. Notably, during the pairing studies, the two size-expanded nucleobases were found to display significant changes in fluorescence on formation of stacked versus unstacked structures, suggesting possible applications in probing nucleic acid structures and biochemical mechanisms.
We report the discovery of a new class of light-sensing molecules. These light sensors are composed of fluorophore oligomers assembled on a DNA backbone. A combinatorial library of tetrafluorophores ...consisting of over 14 000 compounds was synthesized and screened for rapid responses toward light exposure. Among the most light-sensitive molecules, at least three tetramers were found to respond to light exposure with apparent color changes, rather than simple photobleaching.
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